MOF-derived cluster-shaped magnetic nanocomposite with hierarchical pores as an efficient and regenerative adsorbent for chlortetracycline removal

Magnetic nanocomposite with a hierarchical pore structure is an efficient and regenerative adsorbent to eliminate chlortetracycline from water. [Display omitted] The presence of large amounts of antibiotic residues can potentially threaten environmental sustainability and human health. Thus, it is i...

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Published inJournal of colloid and interface science Vol. 586; pp. 433 - 444
Main Authors Fan, Siyu, Qu, Yifan, Yao, Lixian, Ren, Jianhao, Luque, Rafael, He, Zhili, Bai, Cuihua
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 15.03.2021
Subjects
Bimetal-organic framework
Chlortetracycline adsorption
Hierarchical pores
Magnetic nanocomposite
Chlortetracycline adsorption
Hierarchical pores
Magnetic nanocomposite
Bimetal-organic framework
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Summary:Magnetic nanocomposite with a hierarchical pore structure is an efficient and regenerative adsorbent to eliminate chlortetracycline from water. [Display omitted] The presence of large amounts of antibiotic residues can potentially threaten environmental sustainability and human health. Thus, it is imperative to develop convenient and effective technologies for eliminating antibiotics from aquatic environments, which are major contaminant reservoirs. Herein, based on Zn/Fe-MIL-88B, we designed and synthesized a magnetic nanocomposite (MC) that contains hierarchical pores and as an effective and regenerative adsorbent for the removal of chlortetracycline (CTC) from water. The characteristics of the MC and its CTC adsorption performance were investigated systematically. The synthesized MC sample pyrolyzed at 800 °C (MC-800) consisted of metallic iron and N/O-doped graphitic carbon along with cluster-like particles with a mesoporous structure. Further, the adsorption of CTC on MC-800 (maximum adsorption amount of 1158.0 mg/g) could be described using the Freundlich isotherm model and a pseudo-second-order model, indicating that the surface of MC-800 was heterogeneous. The adsorption is likely driven by weak chemical forces, including hydrogen bond formation, cation-π electron donor–acceptor (EDA), and π-π EDA interactions. Finally, MC-800 could be recovered readily through facile magnetic separation and regenerated such that its adsorption rate remained higher than 85% even after five cycles.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2020.10.107